KR100820630B1 - A method of processing data packets - Google Patents

Abstract

A method of processing data packets of a data stream in a communication system is disclosed. In the method, a plurality of data packets from the data stream are analyzed to generate profile data indicating how each one or more portions of the plurality of data packets change from a data packet to a data packet. The profile data then allows a data packet compression method that fits the profile data to be executed on the data packets of the communication system.

Data streams, data packets, profile data, compressors, decompressors, profilers, mobile stations, base stations

Description

A METHOD OF PROCESSING DATA PACKETS

The present invention relates to a method of processing a data packet.

In many digital communication networks, data is transmitted from a transmitting station to a receiving station in discrete variable size portions, generally referred to as packets. Various communication protocols have been developed that define a procedure for transmitting data packets from one station to another on the network and define procedures for determining how packets are handled at the transmitting and receiving stations. For any communication, there are many functions that need to be implemented by the protocol, and in practice many sets of one protocol are used, and each protocol of one suite of protocols handles one or more specific communication aspects. Perhaps the most well known protocol is Transmission Control Protocol / Internet Protocol (TCP / IP), which is widely used on the Internet.

A schematic representation of a simple packet 1 is shown in FIG. Common to all packets, packet 1 consists of two parts: header 2 (also known as protocol control information (PCI)) and payload 3 (actual data sent to the receiving node). It can be thought of. The header 2 includes many fields, represented by 2 ₁ to 2 _N , each of which contains information important for communication. Examples of fields that the header may include include a 'source field' indicating the address of the transmitting station, a 'destination field' indicating the address of the receiving station, a 'data amount field' indicating the size of the payload, and a sequence number of the packet. 'Identification field' that identifies the. Many other field types will be known to those skilled in the art.

 The protocol suite associated with a particular packet does not define the data carried in the payload portion of the packet, but the format of the header, e.g., the field type represented in the header, the length and order of the fields, and how the bit patterns that make up the field are interpreted. To define.

Mobile communication networks and the Internet are converging in terms of their functions. It is desirable for so-called third generation mobile handsets to directly process Internet data packets and allow mobile users to access seamless email access, web browsing, and other services. Protocols such as TCP / IP have been developed primarily for fixed networks, where the bandwidth is relatively rich, rather than wireless networks. When used to carry voice, the message overhead generated from the packet header can reach 75% of the total network capacity, which is not appropriate for mobile networks.

To alleviate this problem, various compression methods have been developed for compressing packet headers in front of packets transmitted on the air interface. One example of such a method is the well-known Van Jacobson scheme, described in RFC 1144.                 

In a conventional header compression system, the entity that performs header compression and the entity that performs subsequent decompression have a header profile of the packet, associated with any conventionally known protocol stack that the entity expects to process. It is pre-made to access stored records.

The header profile effectively defines how the value of each particular field in the header changes from packet to packet and works. For example, a simple header associated with semantic protocol stack Z may have three fields A, B, and C, the profile does not change the value of field A from packet to packet, and the value of field B is random from packet to packet. And the value of field C may be 'field A = fixed, field B = irregular, and field C = linear', meaning that the packet changes linearly from packet to packet, respectively.

Access to the header profile allows the compressor and its associated decompressor to implement compression and subsequent decompression techniques optimized for the particular protocol suite in which it is being used. For example, when receiving a packet having a header defined by semantic protocol stack Z, knowing the header profile associated with protocol stack Z, the compressor is compressed using field static 'encoding field' and field B ' Compressing using 'irregular field encoding', and field C allows to execute a compression method for each packet, which is compressed using 'linear field encoding'. Similarly, knowing the header profile allows the decompressor to implement an optimized decompression method.

Known header compressor / decompressor systems are generally expected to process new types of packet data in which headers are defined by new protocol stacks (or variants of old protocol stacks) that the system did not process previously. To do this, the stored header profile that the system has accessed must first be updated with the header profile associated with the new protocol stack.

Although inconvenient, this is possible for network base-to-base communication, and profile updates can be performed by the network manager but the communication is more difficult to include mobile stations, such as mobile phones.

It is an object of the present invention to overcome or at least alleviate the above problems.

According to the present invention, a method is provided for processing a data packet in a data stream of a communication system, the method comprising receiving a plurality of data packets, analyzing a plurality of data packets, and in response to said analysis, Generating profile data indicating how each one or more portions of the data packets change from data packets to data packets, and generating profile data such that a data packet compression method conforming to the profile data can be executed on the data packets of the data stream. Making it available.

According to the invention, there is also provided an apparatus for processing data packets in a communication system, the apparatus comprising means for receiving a plurality of data packets, means for analyzing the plurality of data packets, in response to the analysis, Means for generating profile data indicating how one or more portions of each of the plurality of packets change from a data packet to a data packet, and making the profile data available for use in selecting a data packet compression method suitable for the profile data. Means for doing so.

According to the present invention, there is also provided a system for processing data packets of a data stream in a communication network, the system receiving a plurality of data packets of a data stream and analyzing the plurality of data packets to determine the plurality of packets. Generating operational data indicating how at least a portion of each operates from a data packet to a data packet and executing a data packet compression method that matches the operational data of the data packet of the data stream. Embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a schematic diagram of a packet,

2 is a block diagram of a system embodying the present invention,

3 is a flow chart illustrating a process used in one embodiment of the present invention;

4 is a conceptual diagram of a packet profile,

5 is a schematic representation of a packet conceptually divided into a string of octets,

6 is a block diagram of another system embodying the present invention, and

7 shows a block diagram of another system embodying the present invention.

With reference to FIG. 2, the illustrated system is provided that embodies the present invention. The system comprises a cellular mobile communication network 10 comprising at least one base station 11 for communicating with at least one mobile terminal or mobile phone 12 operating within the coverage of the base station 11. The mobile network 10 may be, for example, a GSM network or a UMTS network. For example, the structure and function of the components constituting the network of a mobile station, a base station, a base station controller, a gateway, etc. for providing mobile station communication to a base station and connecting the mobile network to another communication network such as a PSTN or the Internet are well known to those skilled in the art. It is not described in detail.

In addition, as is well known to those skilled in the art, a mobile station may include hardware / software capable of processing data transmitted to or from a public data network, such as the Internet, to a mobile network in which the mobile station operates. Such data can take many forms, including, for example, audio, image and text data and web pages.

In the embodiment described in FIG. 2, the mobile station 12 receives packet data transmitted from the Internet 14 to the mobile network 10 from the base station 11 via the air interface 13. The base station 11 is provided with a compressor 15 for compressing the received packet before the packet is transmitted over the air interface 13. The compressor 15 can compress the packet payload, but mainly for compressing the packet header.

The compressor 15 includes a program stored in the base station 11 and executed in a processor (not shown) in the base station to compress the received packet before the packet is sent to the mobile station 12. As noted above, suitable compression algorithms for compressing packets are well known to those skilled in the art.

Similarly, the mobile station 12 is provided with a decompressor 16 to decompress the compressed data received from the base station 11. Decompressor 16 includes a program stored in mobile station 12 and executed in a processor (not shown) in mobile station 12 to decompress the packet. Decompression algorithms for decompressing packets are well known to those skilled in the art.

The base station 11 is further provided with an entity 17 which will later be referred to as a 'profiler' for convenience. Profiler 17 includes software stored in base station 11 and executed in a processor (not shown) located in base station 11. The function of the profiler 17 is to analyze the packets of the packet stream directed to the mobile station 12 to identify an operating pattern or profile of how the value of the corresponding bit sequence for the different packets operates from packet to packet. After identifying this operating pattern, profiler 17 uses this information to decompressor 15 and decompressor 16 so that compressor 15 and decompressor 16 may perform an optimal compression / decompression method for data packets. It transfers to the compressor 16. Thus, unlike conventional systems, compressor 15 and decompressor 16 do not need to have any previous information about the profile of the packets of a given packet stream so that packet compression and subsequent decompression can be achieved. The packet stream can be processed arbitrarily.

2 and 3, an example of a processor used in an embodiment of the present invention is provided. In this example, the field number, order, and length of each field of each packet are known to the compressor 15 in the connection setup. However, the operation of the corresponding field from packet to packet is unknown and determined by the profiler 17.                 

When a data packet begins to arrive at base station 11 (step 20), profiler 17 initiates packet analysis to determine how different the value of the equivalent field from packet to packet is (step 21). In step 22, enough packets have been analyzed by the profiler to determine the operation of at least one field in the packet, and this information is sent to compressor 15 and decompressor 16 (step 23). The profiler 17 continues packet analysis when the packet arrives (step 24) to determine each field's operation and each time the field operation is identified (step 24), and this information is passed to the compressor 15 and decompressor. Is sent to 16 (step 25). This process continues until the profiler 17 writes information about the behavioral pattern in the entire profile of the received packet, ie in each field of the packet (step 26).

A conceptual diagram of a packet profile is shown in FIG. For each field of the packet, the profile indicates the size of the field and how the field changes from packet to packet. In this example, the compressor has previous knowledge of the size of each field so that profiler 17 only needs to determine the operation of each field.

Packets received at the base station 11 may have a number of fields that remain static during the call connection, or are predictable during the call connection, such as changing linearly or changing irregularly during the call connection. Each time profiler 17 informs compressor 15 of the operation of a given field, compressor 15 may implement a suitable compression technique for the field of subsequent packets. For example, a field observed to not change from packet to packet may be deleted from a more compressed packet sent to the mobile station 12 and the field observed to change linearly may use appropriate techniques for linearly changing fields. Can be compressed. Appropriate compression techniques for each type of field operation will be known to those skilled in the art. Notifying decompressor 16 of the operation of a given field allows decompressor 16 to perform a decompression technique that is complementary to the field of the compressed packet.

At connection establishment, compressor 15 will not have information about the operation of any field in the packet. Thus, initially, uncompressed packets will be sent to the mobile station 12. When information about the field behavior is generated by the profiler 17, the compressor 15 begins to execute the compression method for the packet, which would initially be a fairly conservative method. This method is enhanced and refined when the compressor 15 receives more information from the profiler 17, allowing the compressor 15 to implement a suitable compression technique in an increasingly diverse field.

During the call connection between the base station 11 and the mobile station 12, the profiler 17 continues to analyze the operation of the packet field to update the profile at the compressor 15 and the decompressor 16, if necessary. For example, profiler 17 may determine a better understanding of the behavior of a given field or determine that the behavior pattern of a field has changed. In this example, in the case where the degree of compression is increased, for example, if the profiler 17 determines that a particular field is fixed, the update method waits for such an update to reach the decompressor 16 and the compressor 15 becomes more sophisticated. It is desirable to be recognized before running it.

In another example, as a result of the profile created by the profiler, compressor 15 may compress the packet to a greater extent and that is desirable. For example, the profiler 17 may fix a field that has not changed during n packets, and then allow the compressor 15 to quickly compress the field as the profiler 17 determines that the field's behavior has changed. May have been instructed by the compressor 15. Preferably, this change is immediately signaled to the compressor 15 and decompressor 16, and the decompressor 16 is signaled using out-of-band signaling or optionally in-band signaling. For example, the profile update may be encoded into many additional bytes attached to the compressed packet sent to the mobile station 12. The same update can be continuously attached to different compressed packets until an acknowledgment is received that the update has reached the compressor 15.

In addition, multiple type encoding can be associated with a single field, allowing profiler 17 to identify new types of field behavior without necessarily overriding the previously shown behavior pattern. In order for the compressor 15 and the decompressor 16 to make use of this data, the profiler 17 may instruct the compressor 15 and the decompressor 16 the possibility of different encodings. Thus, for example, profiler 17 may indicate that the field is likely to be fixed and the change is unlikely (not zero). This allows the compressor 15 and decompressor 16 to handle minor deviations from the expected behavior without the need for large out-of-band signaling.

In the above example, the number of fields in each packet, the order of the fields, and the length of each field are known to the compressor 15 and the decompressor 16, so that the profiler 17 has a packet on a field basis. It is assumed that can be analyzed. In some examples, if the communication includes a new data type, eg, associated with a new protocol stack, this information will not be available to this entity in the connection setup. In this case, profiler 17 is arranged to analyze the received packet to identify the operational pattern of the equivalent subsection of the packet.

For example, as described in FIG. 5, each entire packet may simply be regarded as an octet string and profiler 17 may be arranged to examine consecutive packets looking for an association between the equivalent octets of the packet. Thus, without identifying field boundaries, profiler 17 profiles packet operation over time based on octets. For example, profiler 17 identifies octets that maintain the same value, make little change, or have a small number of values. As described above with respect to field operation, each time the profiler 17 identifies the operation pattern of a given octet, this information is encoded, thereby decompressing the compressor 15 and implementing an appropriate compression / decompression method. 16 is passed.

As in the known field length example discussed above, during the call connection between the base station 11 and the mobile station 12, the profiler 17 updates the profile at the compressor 15 and the decompressor 16 as needed. Continue to analyze the behavior of the octets.

It will be appreciated that profiling packet operations based on octets is given by way of example only, and profiler 17 may be arranged to profile packet operations on the basis of any convenient size, e.g., 10-bit packet subsection. have.

Another embodiment of the present invention will be described with reference to FIG. 6, and the components described with respect to FIG. 2 will be given the same reference numerals. In this embodiment, the profiler 17 is located at the mobile station 12 rather than the base station 11. In operation, in the connection setup, the packet received at the base station 11 is initially sent to the mobile station 12 without being compressed. At mobile station 12, profiler 17 analyzes the received packet to determine the profile of the packet. As described above, when the frame format of the packet is known, the profiler 17 analyzes the packet on a frame basis. If the frame format is unknown, the profiler 17 analyzes the packet on a subsection basis, eg octet basis.

In either case, whenever the profiler 17 determines the operating pattern of a given field or given subsection, this information is passed to the decompressor 16 and from the mobile station 12 to the compressor 15. It is also transmitted to the base station 11. As in the above example, whenever profiler 17 notifies compressor 15 of the operation of a given field or subsection, the compressor may use a suitable compression technique for the field or subsection of the subsequent packet. The decompressor may use complementary decompression techniques appropriate to the packets received. In this embodiment, the profiler 17 may be adjusted to analyze the received packet before the received packet is input to the decompressor 16 or after being output from the decompressor 16.

Another embodiment of the present invention is described in FIG. 7, and the features described in relation to FIGS. 2 and 6 are again given with reference numerals. In this embodiment, both of the base station 11 and the mobile station 12 are provided with their profiler, denoted 17a and 17b, respectively. In operation, as described above, a packet received at the base station 11 from the Internet 14 is sent to the profiler 17 to profile the operation of either the field of the packet or the subsection of the packet. Is analyzed. As in the prior art, the information of the operation of each field or subsection created by the profiler 17a is transmitted to the compressor 15 executing an appropriate compression technique. Advantageously, in this embodiment, the information determined by the profiler 17a needs to be transmitted from the base station 11 to the mobile station 12 for delivery to the decompressor 16 via the air interface 13. none. Instead, the profiler 17b executes its own analysis of the packet received from the base station 11 to create its own profile of the operation of one of the packet's fields or subsections of the packet and sends it to the profiler 17a. Matches the one written by Information about the operation of each field or subsection created by the profiler 17b is transmitted to the decompressor 16 which implements a suitable decompression technique complementary to the compression technique applied to the compressor 15.

Again, the compressor 15 will initially execute the interactive compression method without the initial packet sent to the mobile station 12 being compressed. As is conventional, the compression method executed by the compressor 15 is enhanced and precisely when the compressor 15 receives information from the profiler 17a which details the operation of the fields (or subsections) of the packet. Will be. Advantageously, this information is generated locally by the second profiler 17b because the information about the field (or subsection) operation required by the decompressor 16 to decompress the packet is generated locally. It does not need to be signaled from 11) to the mobile station 12, thus saving bandwidth usage. It will be understood by those skilled in the art that the two profilers 17a and 17b should be operated in synchronization. For example, such synchronization may be accomplished by sending regular synchronization signals from the base station 11 to the mobile station 12 in a dedicated control channel.

It should be understood that the invention has been described with reference to the Internet and cellular mobile communication network only for purposes of illustration. The present invention may find application in any communication system or combination of systems, where it is desirable to compress a data packet in a packet flow before the packet is received at the receiving station. For example, it can be imagined that the present invention can find particular applications in WLANs.

Thus, while the invention has been described with reference to the preferred embodiments, it should be understood that the embodiments are merely exemplary and that modifications and variations are possible to those skilled in the art without departing from the scope of the invention as defined in the appended claims.

Claims (14)

A method of processing data packets of a data stream in a communication system, the method comprising: Receiving a plurality of data packets from the data stream in a packet analyzer, Analyzing the plurality of data packets to determine how at least one corresponding portion of each of the plurality of data packets varies with each data packet, Generating profile data indicating how the at least one corresponding portion changes; Providing a packet compressor with the profile data to the compressor to execute a packet compression method adapted to the profile data. The method of claim 1, Receiving the profile data at the compressor, Compressing the data packet from the data stream in the compressor using a compression method adapted to the profile data. 3. The method of claim 2, wherein the profile data is transmitted to the compressor via a network link. The method according to any one of claims 1 to 3, Providing a packet decompressor with the profile data to the packet decompressor to execute a packet decompression method adapted to the profile data. The method of claim 4, wherein Receiving the profile data at a decompressor, Decompressing data packets of the data stream in the decompressor using the decompression scheme that fits the profile data. 6. The method of claim 5, wherein the profile data is transmitted to the decompressor via a network link. 7. The method of claim 6, wherein the profile data is transmitted to the decompressor via an air interface. 7. The method of claim 6, wherein the profile data is encoded as a bit string and attached to a data packet for transmission to the decompressor. 4. The method of any one of claims 1 to 3, wherein the profile data indicates how one or more frames of the packet change from packet to packet. 10. The method of claim 9, wherein the one or more frames are header frames. 4. A method as claimed in any preceding claim, wherein the profile data indicates how one or more subsections, which are the lengths of the predetermined number of bits in each packet, change from packet to packet. The method of claim 1, wherein the profile data indicates that the at least one corresponding portion does not change from packet to packet, linearly from packet to packet, or randomly from packet to packet. Characterized in that the method. A computer-readable recording medium having a computer program recorded thereon which implements the method of claim 1 when executed in a processor. An apparatus for processing data packets of a data stream in a communication system, the apparatus comprising: Means for receiving a plurality of data packets from the data stream, Means for analyzing the plurality of data packets to determine how at least one corresponding portion of each of the plurality of data packets varies with each data packet; Means for generating profile data indicating how the at least one corresponding part changes; Means for providing said profile data to said compressor for executing a data packet compression method conforming to said profile data.

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